Cmos memory device with improved sense amplifier biasing

ABSTRACT

A CMOS memory device has a memory cell array, formed on a substrate of a first conductive type, for storing data. The data are input and output via bit line pairs connected to the memory cell array. Sense amplifiers of the first conductive type, which are embedded in wells of a second conductive type, amplify potential differences on the bit line pairs. The sense amplifiers are connected to and driven by a sense amplifier drive signal line. The sense amplifier drive signal line also biases the wells containing the sense amplifiers, thereby preventing latch-up.

This is a division, of application Ser. No. 07/672,359, filed Mar. 22, 1991, U.S. Pat. No. 5,087,957.

BACKGROUND OF THE INVENTION

This invention relates to a complementary metal-oxide-semiconductor (CMOS) memory device such as a dynamic random access memory (RAM), more particularly to a CMOS memory device with improved sense amplifier biasing.

A CMOS device is formed on a substrate of one conductive type having wells or tubs of the opposite conductive type: for example, on a p-type substrate having n-type wells (hereinafter referred to as n-wells). In the device, p-channel metal-oxide-semiconductor (PMOS) transistors are disposed in the n-wells and n-channel metal-oxide-semiconductor (NMOS) transistors are disposed in the p-type substrate outside the n-wells, forming a complementary structure with well-known advantages of low power dissipation.

A CMOS memory device generally has p-channel and n-channel sense amplifiers to amplify data read from the memory cells of the device onto bit lines. Sense amplifiers of one channel type are disposed in wells of the opposite conductive type: for example, p-channel sense amplifiers are disposed in n-wells. The wells are biased to prevent short-circuiting of the power supply, a potentially destructive phenomenon known as latch-up. Prior-art designs use power lines for biasing the wells.

One disadvantage of this scheme is that power lines are subject to voltage fluctuations caused, for example, by variations in the supply voltage, and are also susceptible to voltage drops due to the impedance of the power lines. Such voltage fluctuations and drops can activate parasitic transistors in the well structures, leading to latch-up.

With reference to FIG. 1, for example, a prior-art sense amplifier comprises a pair of PMOS transistors 2 connected to bit lines BL and BL disposed in an n-well 4 in a p-type substrate 6. The sense amplifier is driven by a signal denoted PS which is supplied to the sources 8 of the transistors 2. The n-well 4 is biased by a pair of contacts 10 and 11 connected to power lines VN. Outside the n-well, as part of an adjacent circuit, is a ground contact 12 connected to a ground line Vss.

If a large drop occurs in the VN voltage, parasitic bipolar transistors 14 and 15 in the n-well may turn on, so that when the PS signal is activated a current 11 flows from the source 8 of the PMOS transistors 2 to the p-type substrate 6. Current from the parasitic transistor 15 turns on another parasitic transistor 16 connecting the power contact 11 to the ground contact 12. The power supply is then short circuited; current 12 flows directly from the VN line to ground; latch-up has occurred.

Another disadvantage of this scheme is that the extra required power lines takes up space, leading to undesirably large chip size. FIGS. 2A and 2B, for example, show two typical layouts of the VN bias power lines. In FIG. 2A a main bias power line VNa from a power pad 18 feeds a plurality of liens VN that bias the wells of sense amplifiers 20₁ to 20_(n). In FIG. 2B there are two main power lines VNa and VNb for feeding bias power to both ends of the biasing lines VN. The lines VNa and VNb are used solely for biasing; they do not supply operating power to any circuits. The need to provide such power lines constrains memory design and reduces the space available for memory cells. In FIG. 2B the power line VNb crosses the signal lines PS₁ to PS_(n) by which sense amplifier drive circuits 22₁ to 22_(n) drive the sense amplifiers 20₁ to 20_(n). Accordingly, the line VNb and the lines PS₁ to PS_(n) must be routed in different metal layers, further constraining the circuit design.

With reference to FIGS. 2C and 2D, some prior-art designs attempt to conserve space by using the same power line VNa or lines VNa and VNb both to bias sense-amplifier wells and to supply power to peripheral circuits 24 in the device. Unfortunately, such designs tend to give rise to increased impedance on the power lines, reducing the voltage supplied to the peripheral circuits 24, so that they do not always operate reliably.

SUMMARY OF THE INVENTION

It is accordingly an object of the present invention to prevent latch-up in a CMOS memory device.

Another object of the invention is to conserve space in a CMOS memory device.

Still another object is to enable peripheral circuits in a CMOS memory device to operate reliably.

A CMOS memory device formed on a substrate of a first conductive type comprises a memory cell array for storing data, a plurality of bit line pairs connected to the memory cell array for output of the data, a plurality of wells of a second conductive type disposed in the substrate, and a plurality of sense amplifiers connected to respective bit line pairs for amplifying potential differences on the bit line pairs, one sense amplifier being disposed in each well of the aforementioned plurality of wells. The sense amplifiers are connected to and driven by a sense amplifier drive signal line. The sense amplifier drive signal line also biases the wells in which the sense amplifiers are disposed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view of a prior-art sense amplifier, illustrating parasitic transistors and latch-up current.

FIGS. 2A to 2D are plan views illustrating the biasing of sense amplifiers in prior-art CMOS memory devices.

FIG. 3 is a plan view illustrating the layout of a novel CMOS memory device.

FIG. 4 is a sectional view of a sense amplifier illustrating the novel biasing scheme.

FIG. 5 is a graph illustrating the operation of the sense amplifiers in the novel CMOS memory device.

DETAILED DESCRIPTION OF THE INVENTION

As an illustration of the present invention, a novel CMOS memory device will be described with reference to FIGS. 3 to 5. The novel CMOS memory device is a dynamic RAM, but the invention is not restricted to this type of CMOS memory device; it is applicable to other types of memory as well. It will be assumed that the device is fabricated on a p-type semiconductor substrate, but this too is not a restriction; the invention is also applicable to devices fabricated on n-type substrates.

With reference to FIG. 3, the novel CMOS memory device comprises a memory cell array 26 for storing data and a plurality of bit line pairs BL₁.BL₁ to BL_(n).BL_(n) connected to the memory cell array 26 for input and output of the data. More specifically, the memory cell array 26 comprises n² memory cells 28₁₁ to 28_(nn), where n is an even integer. Memory cells 28₁₁, 28₁₃, . . . , 28₁(n-1) are connected to the bit line BL₁ ; memory cells 28₁₂, 28₁₄, . . . , 28_(1n) are connected to the bit line BL₁ ; memory cells 28_(n1), 28_(n3), . . . , 28_(n)(n-1) are connected to the bit line BL_(n) ; memory cells 28_(n2), 28_(n4), . . . , 28_(nn) are connected to the bit line BL_(n) ; and intermediate memory cells (not shown in the drawing) are connected in like manner to intermediate bit lines (also not shown).

Each memory cell comprises a capacitor 30 and a transistor 32. The transistors 32 are connected to word lines WL₁ to WL_(n), which are driven by a row decoder 34. The structure and operation of the memory cell array 26 and row decoder 34 are well known and will not be described further.

The CMOS memory device in FIG. 3 also has a first column of sense amplifiers 36 and a second column of sense amplifiers 38. The sense amplifiers in these two columns are of opposite conductive types: the first column of sense amplifiers 36 comprises p-channel sense amplifiers 40₁ to 40_(n), while the second column of sense amplifiers comprises n-channel sense amplifiers 42₁ to 42_(n). Since the entire device is formed on a p-type substrate, the p-channel sense amplifiers 40₁ to 40_(n) are disposed in n-type wells (hereinafter referred to as n-wells). The n-wells are not explicitly shown in FIG. 3, but will be illustrated in FIG. 4. The invention relates specifically to the sense amplifiers having channels of the same conductive type as the substrate; that is, to the p-channel sense amplifiers 40₁ to 40_(n) in the first column of sense amplifiers 36 in FIG. 3.

The p-channel sense amplifiers 40₁ to 40_(n) are connected to respective bit line pairs; the sense amplifier 40₁ is connected to the bit lines BL₁ and BL₁ ; the sense amplifier 40_(n) is connected to the bit lines BL_(n) and BL_(n). Each of the p-channel sense amplifiers 40₁ to 40_(n) comprises a first PMOS transistor 44 and a second PMOS transistor 45, the gate and drain electrodes of which are connected to the bit lines. The source electrodes of the PMOS transistors 44 and 45 are connected in common to a sense amplifier drive signal line PS. The function of the sense amplifiers 40₁ to 40_(n) is to amplify potential differences on respective bit line pairs BL₁.BL₁ to BL_(n).BL_(n) when the sense amplifier drive signal line PS is in the active state (high).

Similarly, the n-channel sense amplifiers 42₁ to 42_(n), which comprise NMOS transistors not explicitly shown in the drawing, are driven by another sense amplifier drive signal line line NS. The PS and NS signal lines are activated by a p-channel sense amplifier drive circuit 46 and an n-channel sense amplifier drive circuit 48, respectively.

With reference to FIG. 4, the sense amplifier 40₁, comprising a first transistor 44 a second transistor 45, is disposed in an n-well 50 in the p-type substrate 52. The first transistor 44 comprises a source 50 connected to the sense amplifier drive signal line PS, a gate 52 connected to the first bit line BL₁ in the bit line pair BL₁.BL₁, and a drain 54 connected to the second bit line BL₁ in the bit line pair BL₁.BL₁. The second transistor 45 comprises a source 56 connected to the sense amplifier drive signal line PS, a gate 58 connected to the second bit line BL₁, and a drain 60 connected to the first bit line BL₁. The sources 50 and 56 and the drains 54 and 60 comprise regions in the n-well 50 that are strongly doped with a p-type impurity.

The sense amplifier 40₁ also comprises a first bias contact 62 and a second bias contact 64, both of which are connected to the sense amplifier drive signal line PS. The function of the bias contacts 62 and 64 is to bias the n-well 50 to prevent the latch-up phenomenon described earlier. The bias contacts 62 and 64 comprise regions in the n-well 50 that are strongly doped with an n-type impurity.

The biasing works as follows. The n-well 50 can be considered to contain a pair of parasitic lateral PNP transistors 66 and 68 having their emitters connected via the sources 50 and 56 to the sense amplifier drive signal line PS, their bases connected to the bias contacts 62 and 64, and their collectors connected to the p-type semiconductor substrate 52. Latch-up is prevented by preventing the parasitic transistors 66 and 68 from turning on; this is accomplished by keeping their emitters and bases at the same potential.

The operation of reading data from this CMOS memory device will now be described with reference to FIGS. 3, 4, and 5.

To read data from the memory cell 28_(1n) in FIG. 3, for example, the row decoder 34 decodes a row address signal that causes it to drive the word line WL_(n) to the active state (high). The transistors 32 in the memory cells 28_(1n), . . . , 28_(nn) then turn on, connecting the capacitors 30 in the memory cells 28_(1n), . . . , 28_(nn) to the bit lines BL₁, . . . BL_(n).

FIG. 5 indicates voltage waveforms on the word line WL_(n), the sense amplifier drive signal line PS, the bit line BL₁, and the bit line BL₁. The sense amplifier drive signal line PS and the bit lines BL₁ and BL₁ are precharged to a voltage 1/2.Vcc equal to half the supply voltage. When the word line WL_(n) becomes active, if the capacitor 30 connected to the bit line BL₁ is charged, indicating for example the logic value one, the potential of the bit line BL₁ is raised to a value slightly higher than 1/2.Vcc as shown in the drawing. (If the capacitor 30 connected to the bit line BL₁ were discharged, indicating the logic value zero, the potential of BL₁ would fall to a value slightly lower than 1/2.Vcc.)

After the word line WL_(n) has gone high, the sense amplifier drive signal line PS is driven to the active level (Vcc) as indicated by the solid line labeled PS in FIG. 5. Due to the slight potential difference on the first and second bit lines BL₁ and BL₁, a difference arises between the conductances of the first and second PMOS transistors 44 and 45. The manner in which these transistors 44 and 45 are interconnected with the bit lines BL₁ and BL₁ causes this difference in conductance to increase and the second bit line BL₁ to be pulled up to the Vcc level. The relevant circuit theory is well known and will not be elaborated on.

At the same time, the n-channel sense amplifier 42₁ is driven by the sense amplifier drive signal line NS and operates in like manner to pull the first bit line BL₁ down to the ground level (Vss). The small potential difference on the bit line pair BL₁.BL₁ is thus amplified to the full logic amplitude swing between Vcc and Vss.

A column decoder not shown in the drawings now selects the bit line pair BL₁.BL₁ for output, thus reading the logic value that was stored in the memory cell 28_(1n) in FIG. 3. At the same time, the charges stored in the capacitors 30 in the memory cells 28_(1n), . . . , 28_(nn) are refreshed.

With reference to FIG. 5 again, suppose that the potential on the sense amplifier drive signal line PS does not rise smoothly to Vcc but fluctuates, as shown by the dashed line. Such fluctuations may occur due to fluctuations in the power supply voltage, for example. As a result, the BL₁ line does not rise smoothly to Vcc but also fluctuates, as shown by the solid line in FIG. 5. In the prior art such a fluctuation could lead to latch-up. In the novel CMOS memory device, however, since the emitters and bases of the parasitic PNP transistors 66 and 68 in FIG. 4 are both connected to the sense amplifier drive signal line PS, they are always at the same potential. Hence the parasitic PNP transistors 66 and 68 do not turn on, and latch-up is avoided. This is the first advantage of the novel CMOS memory device.

A second advantage is that special bias power lines such as VNa and VNb in FIGS. 2A and 2B are unnecessary, the biasing being accomplished from the sense amplifier drive signal line PS instead. The overall size of the device can therefore be reduced. Alternatively, the space saved by eliminating the bias power lines VNa and VNb can be exploited to increase the width of other power lines or signal lines to reduce their impedance, thereby increasing the operating speed of the device.

In circuit layouts such as those in FIGS. 2C and 2D, the power lines VNa and VNb can be used exclusively to power the peripheral circuits 24. Since these lines will not be subject to voltage drops associated with the biasing of sense amplifier wells, the peripheral circuits 24 will operate more reliably than in the prior art.

Because the sense amplifier drive signal line PS is connected to the n-well 50, its load capacitance is increased, which could conceivably reduce its signal propagation speed. Such reduction in speed can, however, easily be prevented: ether by using part of the space saved by eliminating the VNa and VNb lines to widen the sense amplifier drive signal line PS, thus reducing its impedance; or by increasing the driving capability of the sense amplifier drive circuit 46 in FIG. 3.

The device illustrated in the drawings is a CMOS memory device with p-channel sense amplifiers disposed in n-wells in a p-type substrate, but with suitable modifications, which will be apparent to one skilled in the art, the illustrated device can be modified to make the invention applicable to any type of CMOS memory device having either a p-channel sense amplifier disposed in an n-well or an n-channel sense amplifier disposed in a p-well, regardless of whether the memory is of the dynamic or static type. Thus the sense amplifiers in general comprise MOS transistors, where MOS may be either PMOS or NMOS. Instead of being connected to the sources of the MOS transistors, the sense amplifier drive signal line PS can be connected to the drains of the MOS transistors, in which case the sources of the MOS transistors are connected to the bit lines. Other modifications, such as modifications in the number or disposition of the bias contacts in the n-wells, can also be made without departing from the spirit and scope of the invention, which should be judged solely from the appended claims. 

What is claimed is:
 1. A semiconductor device comprising:a substrate having a major surface therein and having a first conductivity type; a first region, having a second conductivity type, formed in a first portion of the major surface and extending from the first portion into said substrate; second and third regions, each having the first conductivity type, respectively formed in second and third portions within the first portion and respectively extending from the second and third portions into said first region, said second and third regions defining a channel region therebetween; a gate electrode overlying the channel region; a second conductivity type of heavily doped region formed in a fourth portion within the first portion and extending from the fourth portion into said first region; and said third region being electrically connected to said heavily doped region.
 2. The device according to claim 1 further comprising:a memory cell; a first line coupled to said memory cell; a second bit line supplying a reference voltage to said gate electrode; and an enabling signal line wherein said third and heavily doped region are commonly connected to said enabling signal line, said second region being connected to said first bit line.
 3. A semiconductor device comprising:a substrate having a major surface therein and having a first conductivity type; a first region, having a second conductivity type, formed in a first portion of the major surface and extending from the first portion into said substrate; second and third regions, each having the first conductivity type, respectively formed in second and third portions within the first portion and respectively extending from the second and third portions into said first region, said second and third regions defining a first channel region therebetween; fourth and fifth regions, each having the first conductivity type, respectively formed in fourth and fifth portions within the first portion and respectively extending from the fourth and fifth portions into said first region, said fourth and fifth regions defining a second channel region therebetween; a first gate electrode overlying the first channel region; a second gate electrode overlying the second channel region; a second conductivity type of heavily doped region formed in a sixth portion within the first portion and extending from the sixth portion into said first region; and said third and fourth regions being electrically connected to said heavily doped region.
 4. The device according to claim 3 further comprising:a memory cell; a first bit line coupled to said memory cell; a second bit line commonly supplying a reference voltage to said first gate electrode and fifth region; and an enabling signal line wherein said third, fourth and heavily doped region are commonly connected to said enabling signal line, said second region and second gate electrode being commonly connected to said first bit line.
 5. A semiconductor device comprising:a substrate having a major surface therein and having a first conductivity type; a first region, having a second conductivity type, formed in a first portion of the major surface and extending from the first portion into said substrate; second, third and fourth regions, each having the first conductivity type, respectively formed in second, third and fourth portions within the first portion and respectively extending from the second, third and fourth portions into said first region, said second and third regions defining a first channel region therebetween, said third and fourth regions defining a second channel region therebetween; a first gate electrode overlying the first channel region; a second gate electrode overlying the second channel region; and a second conductivity type of heavily doped region formed in a fifth portion within the first portion and extending from the fifth portion into said first region, said third region being electrically connected to said heavily doped region.
 6. The device according to claim 5 further comprising:a memory cell; a first bit line coupled to said memory cell; a second bit line commonly supplying a reference voltage to said first gate electrode and fourth region; and an enabling signal line wherein said third and heavily doped region are commonly connected to said enabling line, said second region and second gate electrode are commonly connected to said first bit line. 